Latintos stands for "language transformations in texts and open sources." The LATINTOS BLOG highlights different spellings and different meanings of words, phrases and abbreviations as well as their origin. Latintos compares words in different contexts and different languages including scientific and formal languages. Further, name construction is analyzed and applications of systematic names and nomenclature systems are monitored.

Tuesday, June 26, 2012

In geography and ecology, WUI stands for “wildland urban interface,” also written “wildland-urban interface” [1]. This is the belt or zone of transition between urban development and “unoccupied land,” such as forests and wildlife habitats. The WUI itself and adjacent areas on both sides are at high fire risk during dry seasons and conditions of strong winds.

Wendy Tokuda, a journalist and Oakland hills (California) dweller, writes about efforts of WUI management in the Berkeley-Oakland Hills—an area that is particularly at danger when the dry and warm Diablo winds (named after Mount Diablo, a mountain in Contra Costa County northeast of Danville) are blowing from the east [2,3]. Wildfires can be natural, but WUI fires are mostly caused by humans; in Tokuda's words [2]:

Almost all of the fires in the so-called “wildland urban interface”(WUI or “wooie,” as some call it) are caused by people. Some are outright arson, but others are started inadvertently with cars, power tools, or burning leaves or debris. Either way, the bottom line is people cause fires, and there are a lot of people in California.

Wednesday, June 20, 2012

The two volcanoes Mt. Erebus and Mt. Terror on Ross Island—a volcanic formation in Antarctica's Ross Sea—were named in 1841 by Sir James Clark Ross after his expedition ships H.M.S. Erebus and H.M.S. Terror, respectively. H.M.S. Erebus was named after the Greek god of primeval darkness [1-3].

Mt. Erebus is an active stratovolcano, 12,448 ft (3,794 m) high. It is the most southerly active volcano on Earth. Although one of the coldest spots on our planet, Mt. Erebus also is a hot spot: literally, considering its lava lake and fumaroles; and research-wise, considering the interesting occurrence of mosses and microbes, whose origin still is debated. Mt. Erebus belongs to the Pacific Ring of Fire. The New Mexico Institute
of Mining and Technology maintains the Mount Erebus Volcano Observatory (MEVO) on Ross Island, next to Scott Base, which is operated by New Zealand to support field research [4,5].

Both volcanoes have been listed as spectacular skiing destinations with over 10,000 ft (3,000 m) of vertically skiable slopes for downhill enthusiasts [7]. Olivia Judson, in her Erebus article [1] , describes the heavy outfit that researcher on Ross Island wear to protect themselves from extreme weather conditions. What kind of precautions would skiers take? Thinking of skiing Mt. Terror downslope, I get terrified!

Monday, June 4, 2012

The chemical element with atomic number116 was until now addressed as ununhexium (Uuh) using the temporary designator and three-letter atomic symbol system recommended by the International Union of Pure and Applied Chemistry (IUPAC). A few days ago, IUPAC approved the name livermorium to replace the temporary designator ununhexium. The element symbol is Lv.

The name of this synthetic element
honors the Lawrence Livermore National Laboratory in California, which, along with the Flerov
Laboratory of Nuclear Reactions in Russia, has been involved in the discovery and production of various superheavy elements, including
flerovium and livermorium [1].

The most stable isotope known today is livermorium-293, 293Lv, with has a half-life of about 60 ms. Less stable isotopes include 292Lv, 291Lv and 290Lv [2].

Livermorium's “left neighbor” —the element with atomic number 115, ununpentium, with the temporary symbol Uup—is provisionally named eka-bismuth,
since it finds its place below the group 15 (Va) element bismuth in
the periodic table. Following this Mendeleev-type notation, livermorium
can be considered as eka-polonium (its historical name). Livermorium's “next-to-left
neighbor ” with atomic number 114 (formerly ununquadium) is flerovium (Fl). The name flerovium also has just been approved officially by IUPAC [see ununquadium becomes flerovium].

The chemical element with atomic number114 was until now addressed as ununquadium (Uuq) using the temporary designator and three-letter atomic symbol system recommended by the International Union of Pure and Applied Chemistry (IUPAC). A few days ago, IUPAC approved the name flerovium to replace the temporary designator ununquadium. The element symbol is Fl.

Mistaking Fl as the symbol for fluorine, which simply is F, should be unlikely, since the latter is in use for so long. Further, flerovium will not play any major role in composing compounds and writing their formulae, because it is a radioactive chemical element with isotopes exhibiting half-lifes of only a few seconds or less.

The name of this synthetic element honors the Russian physicist Georgiy N. Flerov and also the Flerov Laboratory of Nuclear Reactions in Russia, a facility named after Flerov and known for its production of various superheavy elements, including flerovium [1].

Flerovium's “left neighbor” —the element with atomic number 113, ununtrium, with the temporary symbol Uut—is provisionally named eka-thallium (no permanent IUPAC-approved name yet), since it finds its place below the group 13 (IIIa) element thallium in the periodic table. Following this Mendeleev-type notation, flerovium can be considered as eka-lead or eka-plumbum. Flerovium's “next-to-left neighbor ” with atomic number 112 (formerly ununbium) is officially named copernicium (Cn) [see naming history of copernicium].

Sunday, June 3, 2012

Dehalococcoides ethenogenes is an anaerobic, Gram-positive bacterium (phylum: Chloroflexi, class: Dehalococcoidetes) [1]. Its name, Dehalococcoidesethenogenes, hints at the chemical transformations that it can perform: dehalogenation of halogenated ethene compounds to ethene.

Halogenated solvents such as chlorinated ethenes are environmental pollutants, often with a characteristic of long-term persistence. The discovery that D. ethenogenes can help to convert toxic chemicals into less harmful ones is of interest for the treatment of soil and groundwater, when contaminated with such halogenated hydrocarbons. It has been demonstrated, for example, that D. ethenogenes (strain 195)—transferred into an optimized growth medium—completely decomposes tetrachloroethene by reductive dechlorination [2,3].

An interesting question is if D. ethenogenes evolved in contaminated soil environments and developed the metabolic capability to transform chlorinated hydrocarbons for its own benefit. If so, this would be an example for “natural selection on speed”[4].

Friday, June 1, 2012

Picocyanobacteria (plural of picocyanobacterium) are tiny cyanobacteria—less than two micrometers in size [1]. The prefix pico is derived from the Italian word piccolo for small. The size of picocyanobacteria cells is smaller than that of typical cyanobacteria cells, which ranges from one to forty micrometers [2].

Picocyanobacteria occur in freshwater and marine environments. They are photosynthetic organisms. Their diversity and distribution in dependence on light penetration through water layers and also on other factors is of great interest in ecology. For example, the abundance and composition of picocyanobacterial assemblages has been studied in many lakes of varying trophic state in relation to biomass and dissolved matter [3,4]. A two-year flow-cytometry investigation and in situ experiments in Lake Tahoe revealed seasonal patterns and clear temporal and spatial partitioning between picophytoplankton communities (picocyanobacteria and picoeukaryotes) [4].

Picocyanobacteria are the dominant microbes in the sunlit epipelagic zone of open oceans [5,6]. According to Tim Friend, “these little guys are of tremendous ecological importance” [5]. He informs that various institutions and research centers began sequencing the genomes of marine picocyanobacteria in 2003. Insight in picocyanobacterial metabolisms is critical for our understanding of global environmental and climate changes. Picocyanobacteria species—for example, those in the Synechococcaceae family—have an important role in carbon fixation and nutrient cycling in diverse marine ecosystems [7].